reclamation of degraded land with biosolids
DESCRIPTION
Reclamation of Degraded Land with Biosolids. Impacts of final land use, Impacts of reclamation method. GHG Consequences of Reclamation. F inal land use post-reclamation Reclamation improvements with biosolids Land- and biosolids use interact. Reclamation to forest. - PowerPoint PPT PresentationTRANSCRIPT
Reclamation of Degraded Land with Biosolids
Impacts of final land use,Impacts of reclamation method
GHG Consequences of Reclamation
• Final land use post-reclamation• Reclamation improvements with biosolids• Land- and biosolids use interact
Reclamation to forest
• High gains to Soil and Biomass C• Conventional and residuals reclamation
Partial Reclamation + Development
• Some soil/biomass C• But large GHG costs for construction and use
over life cycle
Field study – Soil C in Reclamation
• Soil C benefits of biosolids reclamation• Compare similar conventional and biosolids
sites up to 30 year post-reclamation
Results: Soil C sequestration
Results: Soil C sequestration
• Soil C increases with biosolids +15 Mg ha-1 (Centralia) +38 Mg ha-1 (Highland Valley)
• 0.11–1.14 Mg CO2e per Mg biosolids
Results: Soil C sequestration
• Increases and efficiency depend upon reclamation conditions and method
Centralia, 0.11 Mg CO2e per tonne: Old sites, 1 m topsoil, very high biosolids rate
Pennsylvania, 0.55 Mg CO2e per tonne: Old sites, relatively good topsoil, moderate biosolids addition
Highland Valley, 1.03 Mg CO2e per tonne: No topsoil, very poor conventional recl., low biosolids rate
Sechelt 1.14 Mg CO2e per tonne: Good response, poor topsoil moderate biosolids addition
Study conclusions
• 55–139 Mg CO2e ha-1 Soil C increase for using residuals• Increase was present even after 30 years• Specific changes related to site conditions and reclamation
history• What about other GHG shifts with reclamation?
Land use
• House or forest? Soil C Biomass C Construction/use/maintenance Operations: transport, soil N2O, fertilizer credit, etc. Competing biosolids uses
Life cycle assessment of reclamation
• What is LCA? Track all
inputs/outputs/activities required
Assign environmental impact
Assess (relative) environmental consequences
Life cycle assessment of reclamation
• Alternate post-reclamation land uses Houses vs. forest Reflects land-use pressures in Puget Sound
Life cycle assessment of reclamation
• 1 ha of degraded land • Urban margin of Puget Sound region, WA• 30 year timeline• Houses or forest
Life cycle assessment of reclamation• “Choose your own adventure”• Natural cover (forest)
Biosolids reclamation Conventional reclamation
• Development
Reclamation – Soil Carbon
• Conventional Reclamation: 110 Mg CO2e
• Biosolids reclamation: 220 Mg CO2e
• Based on C accumulation rate and Mg CO2e per tonne of biosolids
Reclamation – Biomass Carbon
• PNW forests respond to biosolids (soil low in N)
• Conventional: 183 Mg CO2e • Biosolids: 275 Mg CO2e
Conventional Reclamation
• Reclamation to Doug Fir forest
• 110 Mg CO2e soil C
• 183 Mg CO2e biomass C
• 393 Mg CO2e per ha total
Biosolids reclamation• Reclamation to D. Fir• 220 Mg CO2e soil C• 275 Mg CO2e biomass C• 18 Mg CO2e N applied as N2O• 477 Mg CO2e per ha total
Biosolids reclamation GHG emissions?
• Need to consider emissions from biosolids management
• Also alternate biosolids end-uses
Biosolids to Agriculture
• -220 Mg CO2e soil C• -275 Mg CO2e biomass C• +18 Mg CO2e N2O• +2 Mg CO2e transport (50
km)• Net: -475 Mg CO2e
• -140 Mg CO2e soil C • -28 Mg CO2e fertilizer
credit• +11 Mg CO2e transport
(300 km)• Net: -157 Mg CO2e
vs.
Biosolids to Landfill
• -220 Mg CO2e soil C• -275 Mg CO2e biomass C• +18 Mg CO2e N2O• +2 Mg CO2e transport (50
km)• Net: -475 Mg CO2e
• -29 Mg CO2e soil C • 346 Mg CO2e fugitive
GHG• +14 Mg CO2e transport
(350 km)• Net: +331 Mg CO2e
vs.
Net GHG balance of restoring vegetation
• Biosolids reclamation -475 Mg CO2e (30 years, 1 ha, 100 dt biosolids)
• Conventional reclamation -293 Mg CO2e
• What if development is chosen instead?
Suburb development
• Single-family houses• Asphalt roads• Built cover % according
to USGS• Reclaim remaining land
Suburb development: Housing
• US Census population density 3.9 houses/ha @ 243
m2 (~2,500 sq. ft)• LC GHG estimates:
Construction (incl. materials): 283 Mg CO2e
Maintenance/occupation: 989 Mg CO2e
Suburb development: Roads
• USGS % impervious cover 0.44 ha ha-1 suburb
• LC GHG estimates: Construction (incl.
materials): 93 Mg CO2e Maintenance: 42 Mg
CO2e
Net GHG balance of Suburb Development
• +1,272 Mg CO2e houses
• +135 Mg CO2e roads
• -52 Mg CO2e soil C
• -86 Mg CO2e biomass C
• Net: +1,269 Mg CO2e • Extra commuter traffic GHG?
Excluded from LCA but... ca. +1,653 Mg CO2e over 30 yr
Development or Reclamation?
• Net: -293 to -475 Mg CO2e
• Net: +1,269 Mg CO2e
vs.
• Modify and recombine scenarios to look for best and worst cases.
Worst Case
• Low density suburb, and...• Send biosolids to landfill, and...• Conventional reclamation of partial land• +1,600 Mg CO2e – largest emissions, lowest offsets
+
Optimized Case
• Housing construction in urban core, and...• Biosolids for full reclamation• -5 to +141 Mg CO2e – minimized emissions,
maximized offsets
+
Other ecosystem services
• Improved with reclamation over development: Water filtration; Biodiversity; Tourism value
++
+
Conclusions
• Land-use after reclamation has the biggest impact
• Biosolids end-use is also has an impact and is determined in part by land-use choices
• Biosolids in Puget Sound may have best end-use in reclamation but first need to not develop (degraded) land